WO2009094980A1

WO2009094980A1 - Optical-electronic component and method for production thereof

Info

Publication number: WO2009094980A1
Application number: PCT/DE2009/000056
Authority: WO
Inventors: Nikolaus Gmeinwieser; Berthold Hahn
Original assignee: Osram Opto Semiconductors Gmbh
Priority date: 2008-01-31
Filing date: 2009-01-19
Publication date: 2009-08-06
Also published as: CN101933171B; CN101933171A; US20110175121A1; TWI399867B; EP2235759A1; US8686451B2; JP5264935B2; DE102008006988A1; JP2011511446A; KR101640360B1; EP3327796B1; EP3327796A1; KR20150136545A; EP2235759B9; EP2235759B1; KR101573095B1; TW200947762A; KR20100109562A

Abstract

An optical-electronic component (100) comprises a first stack of semiconductor layers (101) which has an active layer (110) set up for emission of radiation, and a primary surface (111). Arranged on this primary surface there is a separating layer (103) which forms a semi-transparent mirror. The optical-electronic component comprises a second stack of semiconductor layers (102) arranged on the separating layer and which has an additional active layer (120) set up for emission of radiation.

Description

description

Optoelectronic component and method for producing an optoelectronic component

The invention relates to an optoelectronic component and to a method for producing an optoelectronic component.

This patent application claims the priority of German patent application 10 2008 006 988.4, the entire disclosure content of which is hereby incorporated by reference into the present patent application.

In order to produce white light with the aid of optoelectronic components, the optoelectronic semiconductor components are conventionally provided with a cladding which contains a converter substance. This converter substance converts the radiation, emitted by the optoelectronic component, of a first wavelength range (primary radiation) into radiation of a second wavelength range (secondary radiation), which differs from the first range. White light can be generated in this way either by mixing the primary radiation with the secondary radiation or by mixing the color components of the converted radiation together to give white light.

A further conventional structure provides for the common use of a plurality of optoelectronic components which in each case emit radiation of different wavelength ranges. The total radiation of the structure comprises the added wavelength ranges of the individual components. It is an object of the invention to provide an optoelectronic component and a method for producing an optoelectronic component, which can be produced simpler and more space-saving and which is more effective.

This object is achieved by an optoelectronic component having the features of claim 1 or a method having the features of claim 14.

An optoelectronic component comprises a first semiconductor layer stack, which has a layer arranged for emission of radiation and a main surface. On this main surface a release layer is arranged, which forms a semitransparent mirror. The optoelectronic component comprises a second semiconductor layer stack, which is arranged on the separating layer and which has a further active layer set up for the emission of radiation and a main surface.

In one embodiment, the radiation that can be emitted by the active layer of the first semiconductor layer stack is e-mitt¬ from the main surface of the first semiconductor layer stack. The emissive radiation of the active layer of the first semiconductor layer stack can be coupled into the second semiconductor layer stack. The emissive radiation of the active layer of the first semiconductor layer stack and the emissive radiation of the active layer of the second semiconductor layer stack may be emissive from the main surface of the second semiconductor layer stack.

The active layers of the two semiconductor layer stacks may be configured to emit radiation of two different wavelength ranges. The separating layer can be used for Be transparent to radiation of a first wavelength range and be configured to reflect radiation of a second wavelength range.

The release layer can furthermore be formed from at least two layers, wherein the layers have at least two different refractive indices. The separation layer may comprise an electrically conductive material, the separation layer may also comprise a dielectric. The release layer may comprise a structuring. The separating layer may also comprise at least one recess into which an electrically conductive material is introduced.

The optoelectronic component may further comprise a first contact element of the first semiconductor layer stack, which is arranged on a further main surface of the first semiconductor layer stack. The other main area lies opposite the first main area. The optoelectronic semiconductor component may comprise a second contact element of the first semiconductor layer stack, which is arranged on a further further main surface of the first semiconductor layer stack. The turn further main surface can be arranged between the main surface and the other main surface. The first contact element and the second contact element can provide an electrical contact to the active layer of the first semiconductor layer stack.

The first and second semiconductor layer stacks of the optoelectronic component each comprise at least one n- and one p-doped layer. The first contact element contacts one of these layers of a first doping type and the second contact element contacts a further one of these layers of a second doping type. On the second semiconductor layer stack may be arranged a third contact element which electrically contacts the active layer of the second semiconductor layer stack. This third contact element may contact a layer of the first doping type.

In a further embodiment, the optoelectronic component may comprise a first contact element, which is arranged on the second semiconductor layer stack, and a second contact element, which is arranged on the second semiconductor layer stack, wherein the first contact element and the second contact element make an electrical contact of the active layer of the provide second semiconductor layer stack. The component may have at least one further contact element, which is arranged on the first semiconductor layer stack and electrically contacts the active layer of the first semiconductor layer stack.

The different semiconductor layer stacks of the optoelectronic component, in particular the respective layers arranged for emission of radiation, can each be individually controllable. In particular, the different semiconductor layer stacks of the optoelectronic component, in particular the respective layers set up for the emission of radiation, can each be individually electrically driven. The optoelectronic component can emit light that is generated by combining the radiation emitted in each case from the different semiconductor layer stacks.

The optoelectronic component may further comprise a converter substance for the partial wavelength conversion of radiation include. The converter substance may be arranged on the main surface of the second semiconductor layer stack. The optoelectronic component can emit radiation which is generated by combining the radiation emitted by the different semiconductor layer stacks and the radiation of the converter substance.

A method for producing an optoelectronic component comprises providing a first substrate, generating a first semiconductor layer stack with an active layer arranged to emit radiation on the first substrate, and detaching the substrate from the semiconductor layer stack.

A second substrate is provided on which a second semiconductor layer stack is formed with an active layer suitable for emission of radiation. The second substrate is detached from the second semiconductor layer stack.

The method further comprises applying a release layer forming a semitransparent mirror to at least one of the semiconductor layer stacks and applying the second semiconductor layer stack to the first semiconductor layer stack such that the separation layer is disposed between the first and second semiconductor layer stacks.

On a main surface of the second semiconductor layer stack opposite further main surface of the second semiconductor layer stack, a first auxiliary carrier can be applied. A second subcarrier may be deposited on the major surface of the second semiconductor layer stack. Of the first subcarrier and the second subcarrier can be detached again. On a main surface of the first semiconductor layer stack, a further auxiliary carrier can be applied and removed again.

The method may further comprise forming at least two contact elements on the active layer of the first semiconductor layer stack. At least one further contact element may be formed on the active layer of the second semiconductor layer stack.

In another embodiment, the method may include forming at least two contact elements on the active layer of the second semiconductor layer stack. At least one further contact element can be formed on the active layer of the first semiconductor layer stack.

The production of the semiconductor layer stacks may each comprise an epitaxial deposition of at least two differently doped semiconductor layers and in each case a structuring of the doped semiconductor layers into their electrical contacts.

In the first semiconductor layer stack, at least one recess may be formed which extends through a layer of a first doping type and through the active layer at least up to a layer of a second doping type.

In the second semiconductor layer stack, at least one recess may be formed which extends through a layer of a first doping type and through the active layer at least up to a layer of a second doping type. The separating layer can be formed from at least two layers, wherein the at least two layers have at least two different refractive indices. The release layer may have a structuring. The separating layer can be formed with at least one recess, and this recess can be filled with an electrically conductive material.

On the main surface of the second semiconductor layer stack, a converter substance for partial wavelength conversion of the emissive radiation can be applied.

Further features, advantages and developments will become apparent from the following in conjunction with Figures 1 to 5 illustrative examples.

Show it:

1 shows a schematic representation of an optoelectronic component according to an embodiment,

FIG. 2 shows a further schematic representation of an optoelectronic component,

FIGS. 3A and 3B show a schematic plan view of an exemplary embodiment of an optoelectronic component or a schematic view of the underside of an optoelectronic component,

FIGS. 4A and 4B show a schematic plan view of a further exemplary embodiment of an optoelectronic component. or a plan view of a bottom side of an optoelectronic component,

FIGS. 5A to 5H are schematic sectional views of a semiconductor layer stack during different process stages.

FIG. 1 shows an optoelectronic component 100 that has a first semiconductor layer stack 101 and a second semiconductor layer stack 102. 1 further shows a separating layer 103 having a recess 104, an active layer 110, a first main surface 111, a first contact element 112, a further main surface 113, a further contact element 114, a further main surface 115, a second active layer 120, a main surface, the second semiconductor layer stack 121, and another contact element 122nd

The semiconductor layer stack 101 comprises three layers in the illustrated figure. A first layer (116) has a first doping type, for example p-doped, and a main surface 113. Opposite the surface 113, the active layer 110 adjoins the first layer. Adjacent to the active layer is another semiconductor layer (117), which is, for example, n-doped. The active layer has a radiation-generating pn junction, which is formed by means of the p-doped and the n-doped layer, which adjoin the active layer.

On the main surface 111, the separation layer 103 may be arranged. The separating layer can surround the recess 104, as in the exemplary embodiment shown. On the separating layer, the second semiconductor layer stack, which may likewise comprise, for example, three layers, be arranged. - S -

The layer (123) adjacent to the release layer is, for example, an n-doped layer. This may be followed by an active layer and a p-doped layer (124). The active layer in turn has a radiation-generating pn junction. Both the first and the second semiconductor layer stack can also have more than three layers, for example an additional buffer layer. The layers which each adjoin the separation layer from the first and the second semiconductor layer stack may have the same doping type.

The separating layer can be formed from several layers. The release layer has at least two layers, which may differ from each other by material or layer thickness. The layers of the release layer may each have different refractive indices. The refractive indices of the layers repeat, for example, at regular intervals. The separating layer is, for example, a dielectric. It may be formed of silicon oxide, of zinc oxide or indium zinc oxide, but it may also comprise another material. The separating layer may comprise a structuring, for example a microstructuring, in particular a nanostructuring, in particular at least one photonic crystal, which is formed on the first, on the second, or on both semiconductor layer stacks.

The contact element 112 may be arranged on the main surface 113 of the example p-doped layer of the first semiconductor layer stack. The contact element may consist of a contact surface, but it may also be formed of a plurality of contact surfaces. In the illustrated embodiment, the major surface 121 is furthest from the main surface 113. The major surface 111 is spaced less than the major surface 121 from the major surface 113. The major surface 115 is spaced less than the major surface 111 from the major surface 113.

The semiconductor layer stack 101 may have a recess for contacting the n-doped layer, for example, which extends through the p-doped region and the active layer. The n-doped layer has in this embodiment, for example, a main surface 115, to which a second contact element 114 may be applied. The semiconductor stack may have such a recess, but it may also have a plurality of such recesses.

The contact elements are formed for example of an electrically conductive material. Via the contact elements, the semiconductor layer stack 101 can be supplied with a voltage when the optoelectronic component is mounted on a corresponding carrier element. The radiation emitted by the semiconductor layer stack, in particular the active layer 110, when the voltage is applied, emerges mainly from the surface 111.

For applying a voltage to the second semiconductor layer stack 102, the contact element 122 may be mounted on the surface 121. The contact element can be made of a contact surface, but it can also be formed of a plurality of contact surfaces. The contact element 122 contacts the example p-doped layer. The example n-doped layer of the layer stack 102 is via the contact element 114, or via the separation layer or by a conductive material contacted in the recess 104 of the release layer. The semiconductor layer stack 102 is thus supplied, for example, by the contact elements 114 and 122 with voltage. The contact elements may have translucent conductors comprising, for example, indium zinc oxide.

In one embodiment, the contact elements may contact the active layers from the direction of the surface 121. At least one recess may be formed through the layer 124 and the layer 120. At least one recess may be formed by the layer 124, the layer 120, the layer 123 and the separating layer. At least one recess may be formed by the layer 124, the layer 120, the layer 123, the separation layer, the layer 117 and the active layer 110. At least one further recess may be formed by other layers. In each case at least one contact element can be arranged in the recess.

The semiconductor layer stacks each emit radiation of different wavelength ranges. For example, the semiconductor layer stack 101 emits radiation having longer wavelengths than the semiconductor layer stack 102. For example, the first semiconductor layer stack 101 emits radiation in the red color region (625 to 740 nm), the semiconductor layer stack 102 radiation in the blue color region (400 to 500 nm).

The separation layer can be as transparent as possible for the wavelength range of the emitted radiation of the semiconductor layer stack 101. For the emitted radiation of the semiconductor layer stack 102, the separation layer is as impermeable as possible and reflects as large a proportion as possible this radiation. Reabsorption of the radiation of the semiconductor layer stack 102 in the semiconductor layer stack 101 can be prevented as far as possible. Both the emitted radiation of the semiconductor layer stack 101 and the emitted radiation of the semiconductor layer stack 102 emerge essentially from the surface 121. The spectral ranges of the respective emitted radiation add up to form an overall spectrum.

By applying different voltages to the respective semiconductor layer stacks, the different wavelength ranges can be involved to different degrees in the overall spectrum. Thus, during operation of the optoelectronic component, setting of a desired color location is possible.

FIG. 2 shows an optoelectronic component 200 with a semiconductor layer stack 201 and a further semiconductor layer stack 202. FIG. 2 also shows a separation layer 203, a converter substance 204, a first active layer 210, a main area 211, a first contact element 212, a second main area 213 second contact element 214, another main surface 215, an active layer 220, another main surface 221, and a contact element 221.

The semiconductor layer stack 201 has at least three layers, for example a p-doped layer, an active layer and an n-doped layer. It also has recesses which extend as far as the n-doped layer, for example. On the n-doped layer opposite to a main surface 213, which is arranged on the example p-doped layer, the separation layer is attached. orders. In the embodiment shown, the separation layer is electrically conductive.

For example, the second semiconductor layer stack 202, which likewise comprises, for example, three layers, is arranged on the separation layer. An n-doped layer is disposed adjacent to the separation layer. Adjacent to the n-doped layer is the active layer and adjacent to the active layer a p-doped layer. The p-doped layer has the main surface 221. On this main surface 221, the converter substance can be arranged.

The converter substance, when excited by electromagnetic radiation of a certain wavelength range, can emit radiation of a different wavelength range. It can contain at least one phosphor. The phosphor may contain inorganic or organic phosphors.

The wavelength ranges of the exciting and the emitted radiation of the converter substance may differ. The converter substance can either convert all the radiation incident on it, it can also convert only part of the incident radiation and let the rest pass without significantly affecting the wavelength range of the transmitted radiation.

In the recesses of the semiconductor layer stack 201, the contact element 214 may be arranged on a main surface 215. On the main surface 213, the further contact element 212 may be arranged. Via the contact elements, the semiconductor layer stack can be supplied with a voltage and thus emit radiation. The radiation is separated from the Layer 203 transraced. The radiation couples into the second semiconductor layer stack 202.

The arrangement of the contact elements is arbitrary. The semiconductor layer stack can be used for p-side contacting and for n-side contacting from its front side, for p-side and n-side contacting from its rear side, for p-side contacting from its front side and for n-side contacting of it Rear side, for n-side contacting of its front side and the p-side contacting of its back, as well as for n- and / or p-side contacting be formed both from the front and from the back.

The semiconductor layer stack 202 can be supplied via the contact element 222 which is arranged, for example, on the main surface 221 and is supplied with voltage via the contact element 214 and thus also via the separation layer 203. The separation layer comprises electrically conductive material in this embodiment. If the separating layer has an electrically insulating effect, it comprises at least one recess which is filled with an electrically conductive material, as shown in FIG. The semiconductor layer stack 202 can thus emit radiation when a voltage is applied. The radiation in a wavelength range emitted by the active layer of the semiconductor layer stack 202 is reflected as well as possible by the separation layer 203.

The emitted radiation of the first semiconductor layer stack lies in a different wavelength range than the emitted radiation of the second semiconductor layer stack. The converter substance converts a part of the radiation that is in the wavelength range of the second semiconductor layer stack lies. The converter substance can transmit radiation that lies in the wavelength range of the first semiconductor layer stack. The total spectrum of the emitted radiation of the semiconductor component can thus be composed, for example, of at least three different wavelength ranges.

FIGS. 3A and 3B show a main surface 301, a contact element 302, a further main surface 303, a further contact element 304, a further main surface 305 and a further contact element 306.

FIG. 3A shows a view of the underside of an optoelectronic component shown, for example, in FIG. The area 301 is the area of an example p-doped semiconductor layer. On this surface, the contact element 302 is applied. The contact element may be a coherent element as in the embodiment shown. But it can also be formed of several individual areas. The component may, for example in the center, have a recess which extends through the, for example, p-doped layer and an active layer up to an n-doped layer, for example. This n-doped layer, for example, has the main surface 303. On this main surface, a further contact element 304 may be applied. The contact elements 302 and 304 serve to be able to supply the semiconductor component with voltage. The doping types of the layers may also be different than in this embodiment, for example, the p-doped layer may be an n-doped layer and vice versa. The underside of the optoelectronic component may have further elements, for example metallizations or carrier substrate. FIG. 3B shows a surface of an optoelectronic component corresponding to FIG. 3A. This has the main surface 305, to which the contact element 306 is applied. The contact element 306 is applied, for example, directly above the contact element 305.

Due to the arrangement of the contact element 306 directly above the contact element 305, the component as a whole has as few areas as possible, from which no radiation is emitted. However, the contact element 306 can also be arranged at a different location of the main surface 305, for example in an edge region. It can also be arranged a plurality of contact elements. In particular, the numbers of contact elements 305 and 306 may differ. A transparent, conductive material may be applied between the contact element and the main surface in order to improve the contact.

FIGS. 4A and 4B show a main surface 401, a first contact element 402, a main surface 403, a second contact element 404, a further main surface 405, a further contact element 406.

FIG. 4A shows the structure shown in FIG. 3A formed four times on a component. On the main surface 401, the contact element 402 may be applied. The contact element may be formed of several individual parts. The recesses, which allow a contacting of the surface 403, can be repeated as often as desired. In the exemplary embodiment shown, four recesses with contact elements 404 are arranged symmetrically, but the recesses can also be arranged differently. FIG. 4B shows a corresponding plan view of a component. The contact elements 406 may be arranged on the main surface 405 above the contact elements 404. You can include as many items as the contact element 404, but it may also be less or more items available. The individual parts of the contact element 406 can be arranged as shown directly above the elements 404, but they can also be arranged differently on the contact surface 405 as desired.

FIG. 5A shows a detail of a substrate wafer 500, a semiconductor layer stack 501, which comprises a doped layer 502, an active layer 503 and a further doped layer 504.

The substrate wafer is formed, for example, of gallium arsenide. The semiconductor layer stack may contain further layers. The substrate wafer may also be formed of another suitable material. In a method, a plurality of semiconductor layer stacks can be formed on a substrate wafer, which are separated in a later method step.

In a method step, the layers of the semiconductor layer stack 501 are grown on the substrate. The semiconductor layer stack is grown, for example, with an n-doped layer starting on the substrate. Subsequently, for example, the active layer and a p-doped layer are grown. Subsequently, the substrate can be removed from the semiconductor layer stack. Before removing the substrate, an auxiliary carrier can be applied to the semiconductor layer stack. FIG. 5B shows the semiconductor layer stack from FIG. 5A without the substrate wafer. On the layer 502, a release layer 505 has been applied. This separating layer has been formed, for example, from several layers. The release layer forms a mirror which is semipermeable. For example, the separation layer is as transparent as possible for certain wavelength ranges and reflects other wavelength ranges.

FIG. 5C shows a further substrate wafer 510, a further semiconductor layer stack 511, which comprises a first doped layer 512, an active layer 513 and a further doped layer 514. The layer stack is grown on the substrate wafer comprising, for example, sapphire. It can also cover more than 3 layers. For example, the semiconductor layer stack is grown starting with an n-doped layer. On the substrate wafer 510, a plurality of semiconductor layer stacks can be formed, which are separated in a later method step.

The release layer 505 may also be applied to the layer stack 511. It can also be applied to one of the layer stacks, but it can also be applied to both stacks of layers.

FIG. 5D shows a method step of an exemplary embodiment in which an auxiliary carrier 515 is applied to the second semiconductor layer stack, in particular to the layer 514.

As shown in FIG. 5E, a second subcarrier 516 may be applied to the semiconductor layer stack 511, in particular to the semiconductor layer stack 511 Layer 512, are applied and the substrate 510 are detached from the semiconductor layer stack.

FIG. 5F is the process step of detaching the first subcarrier 515 already completed. The elements shown in Figure 5B and in Figure 5F can be combined.

FIG. 5G shows the element from FIG. 5B which has been applied to the layer 514 such that the separation layer 505 is arranged between the two layer stacks.

FIG. 5H shows the layer stacks after the second subcarrier 516 has been detached from the layer 512. The layer stack shown now essentially corresponds to that of a component as shown in FIG.

The method may include further method steps, for example applying a converter substrate to the layer 512, or forming contact elements on the semiconductor layers. The method may further comprise forming a recess of the separation layer and filling the separation layer with a conductive material. In particular, the method need not include all of the above-mentioned process steps. By way of example, the first semiconductor layer stack can be applied to the second semiconductor layer stack before the substrate is removed. The production of the semiconductor layer stacks may each have none, one or two auxiliary carriers.

Claims

claims

An optoelectronic device (100) comprising:

a first semiconductor layer stack (101) having an active layer (110) adapted to emit radiation and a major surface (111),

a separation layer (103) arranged on the main surface (111) of the first semiconductor layer stack, wherein the separation layer forms a semitransparent mirror,

a second semiconductor layer stack (102) which is arranged on the separation layer (103) and which has a further active element set up for the emission of radiation

Layer (120) and a main surface (121).

2. The optoelectronic component according to claim 1, wherein the emissable radiation of the active layer (110) of the first semiconductor layer stack (101) couples into the second semiconductor layer stack (102) and the emissive radiation of the active layer (110) of the first semiconductor layer stack (101). and the emissive radiation of the active layer (120) of the second semiconductor layer stack (102) is emissive from the main surface (121) of the second semiconductor layer stack.

3. The optoelectronic component according to claim 1, wherein the active layer of the first semiconductor layer stack is configured to emit radiation of a first wavelength range, and the active layer of the second semiconductor layer stack is configured to emit radiation of a second wavelength range emit.

4. The optoelectronic component according to claim 3, wherein the separation layer (103) is transparent to radiation of the first wavelength range and is designed to reflect radiation of the second wavelength range.

5. Optoelectronic component according to one of claims 1 to 4, wherein the separating layer (103) comprises at least two layers, wherein the layers have at least two different refractive indices.

6. Optoelectronic component according to one of claims 1 to 5, wherein the separating layer (103) comprises an electrically conductive material.

7. The optoelectronic component according to one of claims 1 to 5, wherein the separating layer (103) comprises a dielectric.

8. The optoelectronic component according to one of claims 1 to 7, wherein the separating layer (103) has a structuring.

9. The optoelectronic component according to claim 7 or 8, wherein the separating layer (103) has at least one recess

(104), in which an electrically conductive material is introduced.

10. Optoelectronic component according to one of claims 1 to 9, further comprising:

- A first contact element (112) of the first semiconductor layer stack disposed on another main surface (113) of the first semiconductor layer stack, wherein the other major surface (113) is opposite the main surface (111),

- A second contact element (114) of the first semiconductor layer stack on another turn main surface (115) of the first semiconductor layer stack, wherein the further main surface (115) between the main surface (111) and the other main surface (113) is arranged, wherein the first contact element (112) and the second contact element (114) provide an electrical contact of the active layer (110) of the first semiconductor layer stack.

11. Optoelectronic component according to one of claims 1 to 9, further comprising:

a first contact element, which is arranged on the second semiconductor layer stack, and

a second contact element arranged on the second semiconductor layer stack, wherein the first contact element and the second contact element provide an electrical contact of the active layer of the second semiconductor layer stack.

12. Optoelectronic component according to one of claims 1 to 11, wherein the different semiconductor layer stacks (101, 102) are each individually controllable.

13. The optoelectronic component according to claim 1, further comprising: a converter substance (204) for the partial wavelength conversion of radiation, wherein the converter substance is arranged on the main surface (121, 221) of the second semiconductor layer stack.

14. A method of manufacturing an optoelectronic device, comprising:

Providing a first substrate (500),

Producing a first semiconductor layer stack (501) with an active layer (503) adapted to emit radiation on the first substrate,

Detaching the substrate (500) from the first semiconductor layer stack,

Providing a second substrate (510),

Producing a second semiconductor layer stack (511) with an active layer (513) suitable for emitting radiation on the second substrate,

Detaching the second substrate (510) from the second semiconductor layer stack,

Depositing a release layer (505) forming a semitransparent mirror on at least one of the semiconductor layer stacks,

- applying the second semiconductor layer stack (511) to the first semiconductor layer stack (501) so that the separation layer (505) is arranged between the first and the second semiconductor layer stack.

15. The method of claim 14, comprising:

Forming at least one recess (104) of the separating layer (103),

- Filling the recess (104) of the separating layer (103) with an electrically conductive material.